US2254399A - Concentration testing apparatus and method - Google Patents

Description

Sept. 2, 1941. :J STARR. 2,254,399

CONCENTRATION TESTING APPARATUS AND METHOD- Filed Jan. 26, 1940 Patented Sept. 2, 1941 CONCENTRATION 'ras'rme arranarus AND METHOD James Hammond Starr, La Grange, Ill., assignor to Dearborn Chemical 00., Chicago, 111., a corporation of Illinois Application January 26, 1940, Serial No. 315,682

18 Claims. (01. 175-183) The present invention relates to a novel method and apparatus for measuring the conductivity of various media, but finds particular use in measuring fluids, usually liquids to determine the concentration of impurities or other substances therein.

For example, the invention may be utilized to V determine the amount of salt content in water,

the amount of foreign matter and the like in boiler water, condensed steam, etc.

' Conductivity testing devices in general include some means for subjecting the medium to be tested to the measured flow of current between a pair of electrodes. In some cases these electrodes form a part of a cell or cartridge which may be immersed'bodily inthe medium, while in other cases a portion or sample of the medium is placed in a separate container having electrodes arranged therein. The present invention is primarily concerned with arrangements of the latter type, and contemplates as a primary object the provision of an improved cell for such purpose, whichis so arrangedas to materially facilitate the" carrying out of the testing operations 1 with a minimum of inconvenience and greater sustained accuracy than is now possible in the commonly known types of cells or cartridges.

A further object is to provide an improved testing cell that is so arranged that the conductivity measurement will always be made on a predeterminedyolumetiic quantity of predetermined relative dimensions of the fluid being tested, thus eliminating to a large extent the possibilities of error.

A further-object is to provide an improved testing cell embodying novel temperature responsive means for indicating th I temperature of the liquid in the cell.

A further object is convenience, thus assuring that the accuracy of the cell is maintained, even though the surfaces of the electrodes may be attacked chemically or electrolytically, or may be subject to the deposit of film which would, if permitted to remain, alter the apparent conductivity of the sample in normal operation.

to provide a ceiloi the type described having electrodes which may be 49 inspected, cleaned, or replaced with minimum in- 1 Another object or the inventionis to provide a cell of the herein described type having removable electrodes which are so arranged as to prevent their .being' simultaneously engageable against a flat metallic surface and thus cause a short circuit tothe testing ap provide 1 ll f in the formation of a bottom portion it on the Still another object is to as Bakelite. plug portion I 4 which is rabbeted at its lowerthe herein described improved overflow means for receiving surplus liquid placed in the cell over and above a predetermined volumetric amount, thus assuring thatthe test will always be performed on a predetermined unit amoun of the liquid.

Other objects and features of the invention will more fully appear from the following detailed description taken in connection with the accompanying drawing which illustrates a single embodiment thereof, and in which:

Figure l is a view in elevation of a testing cell embodying the features of the present invention,

thisview additionally schematically showing one form of electrical system may be utilized;

Figure 2 is an enlarged plan view of the cell; Figure 3 is an enlarged sectional view through the cell showing its constructional details taken substantially on line-IIII1I of Figure 2; and

Figure 4 is a detailed view in section of the cup portion of the cell showing its construction.v

As shown on the drawing:

For purposes of illustrationand without limiting myself thereto, there is specifically illustrated a form of the invention particularly applicable to the testing of conductivity of liquids and which includes a testing-cell generally indicated by the numeral l0.

As will beclearly evident from the drawing, the testing cell comprises two major parts, namely, a cup-shaped' container II and a closure for the container as indicated at l2.

As more specifically shown in Figures 3 and. 4,

the cup-shaped container may be of any desirable outside shape, but is preferably provided with a circular interior open at its top. The container is preferably made-from'suitable insulating material such asfBakeli The inside of the container is constructed intermediate its top and bottom with an outwardlyoffset shoulder it which forms the Junction between the lower por-' tion of the container of smaller diameter and the upper portion of the container of larger diameter. 4 r

The closure for the container is likewise-preferably constructed of an insulating material such The closure comprises a circular most edge to form a seating shoulder l5 adapted to seat on the shoulder i3 of the container when the plug is placed in the top of the container. It

will be noted that this construction also results with which the cell plug which projects into the lower portion of the container below the shoulder l3 thereof.

This projection of the plug in closing position as shown in Figure 3 causes the plug to cooperate with the container to definea testing compartment or chamber H in the container, this chamber having a predetermined volumetric content. I

Centrally extending through the plug is a tube l8, which is preferably of insulating material, the lowermost end of this tube being arranged to project into the chamber I1 and being provided in its projecting portion with wall openings I9. Intermediate its ends, and exteriorly of the housing formed by the container II and the plug 12, the tube is provided with a longitudinally extending slot or window 20. The tube l8 forms a protective housing for a thermometer 2| which may be supported in any suitable manner within the tube with its bulb portion 22 within the projecting lowermost end of the tube and its scale portion 23 so disposed that temperature indicating indicia 24 on the scale may be viewed through the window 20 of the tube.

Surrounding the tube l8 and circumferentially spaced are a plurality of passageways 25 having their axes in parallel relation with theaxis of the tube i8, these passageways communicating at their lowermost ends with the chamber I1 and at their uppermost ends with the exterior of the housing. g

Diametrically disposed on opposite sides of the tube l8 are terminal studs 26 which extend through suitable passageways in the plug it and are provided at their, lowermost ends with head portions which define electrodes 21 and 28 arranged to project into the chamber 11, these electrodes being disposed on opposite sides of the projecting lowermost. end of the tube l8.

The uppermost end of each terminal studis threaded and provided with a suitable securing nut 21', by means of which the terminal studs may be secured in the plug. It is preferable to provide a suitable washer 28' of insulating material between the nut 21' and the adjacent sur-- face of the plug. Suitable insulated nuts 29 are provided for threading on to the extreme ends transformer to give a predetermined voltage, depending upon the temperature of the liquid to be tested. In adjusting the transformer for such voltage, a load impedance 32 is first connected across the transformer secondary by means of a switch 33. The testing circuit having thus been calibrated for the temperature of the liquid being tested, the switch 33 is opened and a milliammeter 34 connected in series with the electrodes 2! and 28 by closing a switch 35.

The milliammeter then indicates on a suitable scale the amount ofv current flowing through the liquid between the electrodes 21 and 28. The scale of the milliammeter may indicate directly in amperes and be compared with a standard scale giving milliamperes in terms of concentration at various temperatures of the liquid. Moreover, if desired, the scale of the milliammeter -may be calibrated to read directly in terms of concentration in the liquid being tested.

In placing the liquid in the container ll,-

enough liquid is placed in the container to bring its level just to the shoulder B. It will be noted that when the plug i4 is placedin position in the top end of the container, the bottom pro- 0 jecting portion It extends into the liquid and acts as a plunger to force any surplus liquid within the chamber ll up into the passageways 25 and the interior of the tube i8. Due to this action, the electrodes during each test operate on a unit volumetric quantity of the liquid being tested. 'It will be noted that the liquid forced into the passageways 25 is separated between the passageways by insulating material so that a current flow path is not established in the portions of the liquid lying within the passageways 25 or the tube I! above the bottom of the plug it. Temperature readings for use in calibrating the electrical system and adjusting the secondary voltage of the transformer 30 are readily obtainable from the thermometer 2| readings.

In the event that liquid should be forced out of the uppermost ends'of the passageways 25, this liquid will run off and the insulating washers 28 on the terminal studs will prevent the establishing of a leakage circuit between the terminal of the threaded portion of the studs, these nuts a flat metallic surface and thus.short the elec'-' trical circuit connected thereto.

The cell of the present invention may be utilized with electrical systems embodying various arrangements. One such arrangement with which the cell may be utilized is schematically disclosed in Figure 1. In this system; there is provided a suitable transformer 30 which may be connected on its primary side too. suitable source of electrical energy. 'Iliis transformer" preferably has an adjustable secondary to enable adjustment of the secondary voltage to be used in the testing operation. A suitable voltmeter 3i may be connected across the secondary winding ofthe transformer to indicate the secondary voltage supplied to the testing circuit.

It is the usual practice in this type of appastuds connected to the electrodes.

During the testing of fluids it is extremely important in order to obtain accurate readings that the electrodes shall be kept clean and free from film deposits. In the' cell structure of the present invention the electrodes are disposed so that they may readily be inspected, and should a film be deposited, this film may be easily removed without having to remove the electrodes.

Moreover, if the electrode surfaces should be attacked chemically or electrically, which would alter the test readings, the cell construction is such as to enable the electrodes to be easily replaced with a minimum of inconvenience.

In order to remove an electrode, it is only necessary to unscrew the nuts 21' and 29 from its threaded end, whereupon the electrode may be longitudinally withdrawn from the associated plug'and a-replacement electrode inserted and secured in its place.

Thus the accuracy of the cell may be maintained and dependable readings assured when my ratus to first adjust the secondary voltage of the 7 improved cell is utilized.

vFrom the foregoing description, it will be apparent that the present invention provides an improved cell for use in the testing 01 the electrical conductivity of fluids,'particularly liquids, which is so arranged as to materially facilitate the carrying out of the testing operations with a minimum of inconvenience and with greater sustained accuracy than is now possible in the commonly known cell arrangements} which meas-. ures the conductivity on a predetermined volua largev extent the possibilities of error; which includes novel temperature responsive means for indicating the temperature of the liquid in the cell; which is so arranged as to prevent inadvertently shortcircuiting the electrodes by simultaneouslycontacting them with a flat metallic surface; which embodies improved overflow means for receiving surplus liquid placed in the cell, when the amount of liquid placed therein exceeds a predetermined volumetric amount; and

metric quantity of the fluid, this eliminating to be tested, spaced electrodes of like material engageable by the fluid, and a thermometer having a bulb portion arranged to contact the fluid within the compartment between the electrodes, saidithermometer including means for indicating exteriorly of the housing the temperature of the fluid within the compartment.

"7. A fluid conductivity testing device comprising ahousing defining a compartment for receiving a predetermined amount of the fluid to be tested, spaced electrodes engageable By the which permits the electrodes to beinspected,

cleaned, or replaced with a minimum of inconvenience.

Now it is, of course, to be understood that'although I' have described in detail the preferred embodiment of my invention, the invention is not to be thus limited but only in so far as de-' fined by the scope and spirit of the appended claims.

I claim as my invention:

1-. A fluid conductivity testing device comprising a housing defining an open receptacle for receiving an isolated sample of a fluid to be tested, a removable closure for the receptacle, said receptacle and closure defining a testing compartment lined with insulating material, and a pair of electrodes of like material carried by the closure arranged to contact the fluid in the testing compartment, when the closure is in. receptacle closing position.

2. A conductivity testing device comprising an open container for material to be tested, .a closure for the container arranged to extend into the container and form a closed compartment of fluid, a; thermometer having a bulb portlqn arranged to contact the fluid within the compartment between the electrodes, said thermometer having a temperature indicating scale disposed exteriorly of the housing, and a shield between said bulb and the electrodes.

8. As all article of manufacture, 'a fluid conductivity testing device comprising a housing defining a compartment for receiving a sample of the fluid to be tested, spaced electrodes engageopen end of the member and cooperating therepredetermined size, means for receiving any sur- 40 plus materialover that required to completely fill the compartment, and spaced electrodes of like material in said compartment ing said material therein.

3. A fluid conductivity testing cell comprising a container defining a compartment oi'predetermined size for receiving fluid to be tested, and a pair of spaced testing electrodes of like material in said compartment for contacting the fluid therein and adapted to have a potential applied thereto, said container having a passageway out of the direct path between said electrodes for receiving any surplus fluid over that required to completely fill said compartment.

for contactwith to define a compartment of predetermined size, a plurality of spaced electrodes carried by the plug engageable by the fluid in said compartment, and a projection on the plug between the electrodes extending past the outermost end portions of the electrodes for preventing inadvertently connecting the electrodes by engaging their outermost ends against a flat metallic surface. v

10. As an article of manufacture, a fluid conductivity'testing device comprising a cup-shaped 4. A fluid conductivity testing cell-comprising a container defining a fluid receiving compartment of predetermined size, a pair of spaced testing electrodes in said compartment for contacting the fluid therein and adapted to have a member for receiving a quantity of the fluid to be tested, a plug removably disposable in the' open end of the member and cooperating thereth to define a testing chamber, and a plurality f electrodes extending into said chamber, said plug having a plurality of passageways for receiving overflow from the chamber of fluid in member for receiving a quantity of the fluid to be tested, a plug removably' disposable in the potential applied thereto, said container having a plurality of passageways for receiving surplus fluid over that required to completely flll open end of the member and cooperating therewith to define a testing chamber, said plug having a passageway communicating with the chamber for receiving overflow therefrom of fluid in excess of that required to completely said compartment, and baflles of insulating material separating the fluid in said passageways.

5. A fluid conductivity testing device com-9 prising a housing defining a compartment walled with insulating material for receiving a prede termined amount of the fluid to be tested, spaced electrodes of like material contactable by the fluid, and temperature responsive means for in- 7 dicating externally of said housing the'te'mpera- 12. Afluid conductivity testing cell comprising a container disposed to receive a sample of the fluid to be tested, means for isolating and determining a portion of said samples of predetermined dimensions, a plurality of electrodes 01 like material immersible in the isolated porceivinga predetermined amount of the fluidto tion of the said sample and in predetermined sional relation to the boundaries thereof, temperature indicating means immersible in the iso- 13. A fluid conductivity testing cell comprising a container disposed to receive a sample of the fluid to be tested, means for isolating and determining a portion of said sample of predetermined dimensions, a plurality of electrodes immersible in the isolated portion of the said sample and in predetermined dimensional relation to the boundaries thereof, temperature indicating means immersible in the isolated portion of said sample and in predetermined dimensional relation to the boundaries thereof, and means for protecting the temperature means and minimizing the possibility of inadvertent short circuiting of said electrodes when removed from said cell.

14. A fluid conductivity testing cell comprising a container disposed to receive a sample of the fluid to be tested, means for isolating and determining a portion of said sample of predetermined dimensions, a plurality of electrodes immersible in the isolated portion of the said sample and in predetermined dimensional relation to the boundaries thereof, temperature indicating means immersible in the isolated portion of said sample and in predetermined dimensional relation to the boundaries thereof, protective means to minimize the probability of inadvertent breakage of said temperature indicating means, and protective means to minimize inadvertent short circuiting of said electrodes when removed from said cell.

15. A fluid conductivity testing cell comprising a container disposed to receive a sample of the fluid to be tested, means for isolating and determining a portion of said sample of. predetermined dimensions, a plurality of replaceable electrodes immersible in the isolated portion of the said sample and in predetermined dimenlated portion of said sample and in predetermined dimensional relation to the boundaries thereof, and protective means extending exteriorly and interiorly'of said container to minimize the probability of inadvertent breakage of said temperature indicating means.

16. A method of measuring the electrical conductivity of a fluid, which method includes the steps of: initially confining an amount of the fluid to be tested in a chamber, disposing a plurality of electrodes in the fluid, reducing the size of the chamber to obtain a predetermined volumetric quantity of the fluid, and then subjecting said predetermined quantity of fluid to a measured flow of current between said electrodes.

1'1. A fluid conductivity testing device comprising a cup-shaped member of insulating material for receiving an isolated quantity of a fluid to be tested, a plug of'insulating material slidably insertable into the open end of the member,

said plug having a plurality of spaced axially extending passageways therethrough, means limiting the extent of insertion of said plug into the member, said plug and member cooperating to define a compartment of predetermined size and certain of said passageways defining re- I ceivers for any surplus fluid over that required to completely flll said compartment, and electrodes contactable by the fluid in said compartment, said electrodes having connection portions points therein.

JAMES HAMMOND STARR.

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